Normalized to: Jr.
[1]
oai:arXiv.org:astro-ph/0007312 [pdf] - 37150
Quasar Variability in the Framework of Poissonian Models
Submitted: 2000-07-20
In this paper we review the basic Poissonian formulation of quasar
variability, using it as a mathematical tool to extract relevant parameters
such as the energy, rate and lifetimes of the flares through the analysis of
observed light curves. It is shown that in this very general framework the well
established anti-correlation between variability amplitude and wavelength can
only be understood as an effect of an underlying spectral component which
remains stable on long time-scales, and is redder than the variable component.
The formalism is applied to the B and R light curves of 42 PG quasars collected
by the Wise Observatory group. Variability indices for these data are obtained
with a Structure Function analysis. The mean number of living flares is
constrained to be in the range between 5 and 100, while their rates are found
to be of order 1--100 per yr. Monochromatic optical flare energies of
10^{46-48} erg/A and life-times of 0.5 to 3 yr are derived. Lower limits of
typically 25% are established for the contribution of a non-variable component
in the R band. The substantial diversity in these properties among quasars
invalidates simple versions of the Poissonian model in which flare energies,
lifetimes and the background contribution are treated as universal invariants.
The good correlation between the EW(H_beta) and the long term variability
amplitude is interpreted in a scenario where only the variable component
participates in the ionization of the line emitting gas. This idea is
consistent with the observed trends of the variability amplitude with lambda,
EW(HeII) and the X-ray to optical spectral index (abridged).
[
2]
oai:arXiv.org:astro-ph/0007312 [pdf] - 37150
Quasar Variability in the Framework of Poissonian Models
Submitted: 2000-07-20
In this paper we review the basic Poissonian formulation of quasar
variability, using it as a mathematical tool to extract relevant parameters
such as the energy, rate and lifetimes of the flares through the analysis of
observed light curves. It is shown that in this very general framework the well
established anti-correlation between variability amplitude and wavelength can
only be understood as an effect of an underlying spectral component which
remains stable on long time-scales, and is redder than the variable component.
The formalism is applied to the B and R light curves of 42 PG quasars collected
by the Wise Observatory group. Variability indices for these data are obtained
with a Structure Function analysis. The mean number of living flares is
constrained to be in the range between 5 and 100, while their rates are found
to be of order 1--100 per yr. Monochromatic optical flare energies of
10^{46-48} erg/A and life-times of 0.5 to 3 yr are derived. Lower limits of
typically 25% are established for the contribution of a non-variable component
in the R band. The substantial diversity in these properties among quasars
invalidates simple versions of the Poissonian model in which flare energies,
lifetimes and the background contribution are treated as universal invariants.
The good correlation between the EW(H_beta) and the long term variability
amplitude is interpreted in a scenario where only the variable component
participates in the ionization of the line emitting gas. This idea is
consistent with the observed trends of the variability amplitude with lambda,
EW(HeII) and the X-ray to optical spectral index (abridged).
[3]
oai:arXiv.org:astro-ph/0002180 [pdf] - 34523
An Empirical Test and Calibration of H II Region Diagnostics
Submitted: 2000-02-08
We present spectrophotometry in the 3600-9700 A region for a sample of 39 H
II regions in the Galaxy and Magellanic Clouds, for which independent
information is available on the spectral types and effective temperatures of
the ionizing stars. The spectra have been used to evaluate nebular diagnostics
of stellar temperature, metal abundance, and ionization parameter, and compare
the observed behavior of the line indices with predictions of nebular
photoionization models. We observe a strong degeneracy between forbidden-line
sequences produced by changes in stellar Teff and metal abundance, which
severely complicates the application of many forbidden-line diagnostics to
extragalactic H II regions. Our data confirm however that the Edmunds and Pagel
[O II]+[O III] abundance index and the Vilchez and Pagel `eta' index provide
more robust diagnostics of metal abundance and stellar effective temperature,
respectively. A comparison of the fractional helium ionization of the H II
regions with stellar temperature confirms the reliability of the spectral type
vs Teff calibration for the relevant temperature range Teff < 38000 K. We use
empirical relations between the nebular hardness indices and Teff to
reinvestigate the case for systematic variations in the stellar effective
temperatures and the upper IMFs of massive stars in extragalactic H II regions.
The data are consistent with a significant softening of the ionizing spectra
(consistent with cooler stellar temperatures) with increasing metal abundance,
especially for Z less than solar. However unresolved degeneracies between Z and
Teff still complicate the interpretation of this result.